Predetermined temperature profile controlled concrete curing container

ABSTRACT

The invention comprises a method of curing concrete. The method comprises placing a concrete cylinder in an insulated container having a sufficient quantity of water therein so that the concrete cylinder is submerged in and surrounded by the water and selectively adding heat to the quantity of water in an insulated container, so that the temperature of the quantity of water follows a predetermined temperature profile.

CROSS REFERENCE TO RELATED APPLICATIONS

The present application is a continuation of application Ser. No. 14/734,184 filed Jun. 9, 2015, now U.S. Pat. No. 10,640,425, which claims the benefit of the filing date of provisional application Ser. No. 60/010,273 filed Jun. 10, 2014.

FIELD OF THE INVENTION

The present invention generally relates to concrete curing. More particularly, this invention relates to a system for controlling the temperature of concrete cylinders in a concrete curing box or cabinet. The present invention also relates to curing concrete over time in a concrete curing box or cabinet according to a predetermined temperature profile. The present invention also relates to a system for controlling the temperature in a concrete curing box or cabinet according to a predetermined temperature profile.

BACKGROUND OF THE INVENTION

Concrete walls, and other concrete structures and objects, traditionally are made by building a form or a mold. The forms and molds are usually made from wood, plywood, metal and other structural members. Unhardened (plastic) concrete is poured into the space defined by opposed spaced form members. Once the concrete hardens sufficiently, although not completely, the forms are removed leaving a concrete wall, or other concrete structure, structural member or concrete object, exposed to ambient temperatures. The unprotected concrete walls, structures or objects are then exposed to the elements during the remainder of the curing process. The exposure of the concrete to the elements, especially temperature variations, often makes the curing of the concrete a slow process and the ultimate strength difficult to control or predict. To compensate for these losses, larger amounts of portland cement sometimes are used than otherwise would be necessary in order to insure sufficient concrete strength is achieved.

The curing of plastic concrete requires two elements, water and heat, to fully, hydrate the cementitious material. The curing of plastic concrete is an exothermic process. This heat is produced by the hydration of the portland cement, or other cementitious materials, that make up the concrete. Initially, the hydration process produces a relatively large amount of heat. As the hydration process proceeds, the rate of hydration slows thereby reducing the rate of heat production. At the same time, moisture in the concrete is lost to the environment. If one monitors the temperature of concrete during the curing process, it produces a relatively large increase in temperature which then decreases rapidly over time. This chemical reaction is temperature dependent. That is, the hydration process, and consequently the strength gain, proceeds faster at higher temperature and slower at lower temperature. In traditional curing of concrete, first, the heat is lost which slows the hydration process; then; the moisture is lost making it difficult for the cementitious material to fully hydrate, and, therefore, impossible for the concrete to achieve its maxim strength.

Concrete in conventional concrete forms or molds is typically exposed to the elements. Conventional forms or molds provide little insulation to the concrete contained therein. Therefore, heat produced within the concrete form or mold due to the hydration process usually is lost through a conventional concrete form or mold relatively quickly. Thus, the temperature of the plastic concrete may initially rise 20 to 40° C., or more, above ambient temperature due to the initial hydration process and then fall relatively quickly to ambient temperature, such as within 12 to 36 hours. This initial relatively large temperature drop may result is concrete shrinkage and/or concrete cracking. The remainder of the curing process then proceeds at approximately ambient temperatures, because the relatively small amount of additional heat produced by the remaining hydration process is relatively quickly lost through the uninsulated concrete form or mold. The concrete is therefore subjected to the hourly or daily fluctuations of ambient temperature from hour-to-hour, from day-to-night and from day-to-day. Failure to cure the concrete under ideal temperature and moisture conditions affects the ultimate strength and durability of the concrete. In colder weather; concrete work may even come to a halt since concrete will freeze, or not gain much strength at all, at relatively low temperatures. By definition (ACI 306), cold weather conditions exist when “ . . . for more than 3 consecutive days, the average daily temperature is less than 40 degrees Fahrenheit and the air temperature is not greater than 50 degrees Fahrenheit for more than one-half of any 24 hour period.” Therefore, in order for hydration to take place, the temperature of concrete must be above 40 OF; below 40° F., the hydration process slows and at some point may stop altogether. It is typically recommended that concrete be moisture cured for 28 days to fully hydrate the concrete. However, this is seldom possible to achieve in commercial practice.

It is typical that concrete cylinders are poured from the same concrete mix used to form a wall, slab or other structure. These cylinders are then cured under water at 72 F. according to ASTM This method provides a standard by which the compressive strength of concrete can be determined. However, it bears little relationship to the concrete that is cured under ambient conditions.

Engius, Inc. has developed the IntelliCure Match concrete curing box. This concrete curing box comprises an insulated container with both heating and cooling elements disposed below the water level in the curing box. A temperature sensor disposed below the water level sends signals to a microprocessor. The microprocessor controls the amount of heating or cooling provided to the water in the curing box, A temperature sensor, such as the Intellirock sensor, is embedded in a curing concrete wall, slab or other concrete structure of interest that is subjected to the environment. The Intellirock sensor senses the actual temperature of the curing concrete. A signal is provided by the Intellirock sensor to the microprocessor. The microprocessor is programmed so that it controls the heating or cooling of the water in the curing box so that the temperature of the water matches the temperature of the curing concrete wall, slab or other concrete structure in which the Intellirock sensor is embedded. The IntelliCure Match concrete curing box therefore duplicates the temperature conditions actually experienced by the curing concrete wall, slab or other concrete structure of interest. The IntelliCure Match concrete curing box can also maintain the temperature of the water in the curing box at any desired constant temperature level.

Although the IntelliCure Match concrete curing box provides a useful function, it cannot control the temperature within the concrete curing box according to a predetermined temperature profile as a function of time. Curing concrete according to a predetermined temperature profile as a function of time provides desirable advantages, as disclosed in U.S. Pat. No. 8,545,749 (the disclosure of which is incorporated herein by reference in its entirety).

Therefore, it would be desirable to provide a concrete curing box that can cure concrete cylinders according to a predetermined temperature profile as a function of time. It would also be desirable to provide a concrete curing system that adjusts the temperature of curing concrete cylinders so that the temperature follows a predetermined temperature profile as a function of time.

SUMMARY OF THE INVENTION

The present invention satisfies the foregoing needs by providing an improved system for curing concrete under predetermined controlled temperature conditions over time.

In one disclosed embodiment, the present invention comprises a method. The method comprises placing a quantity of plastic concrete in an insulated container having a sufficient quantity of water therein so that the plastic concrete is submerged in and surrounded by the water and selectively adding heat to the water in the insulated container, so that the temperature of the water follows a predetermined temperature profile as a function of time during at least a portion of the concrete curing process.

In another disclosed embodiment, the present invention comprises a method. The method comprises placing a concrete cylinder in an insulated container having a sufficient quantity of water therein so that the concrete cylinder is submerged in and surrounded by the water and controlling the temperature of the water so that the water temperature follows a predetermined concrete curing temperature profile as a function of time.

In another disclosed embodiment, the present invention comprises a method. The method comprises placing a concrete cylinder in a quantity of water, detecting the temperature of the quantity of water, selectively adding heat to the water in response to the detected temperature and controlling the temperature of the water so that the water temperature follows a predetermined concrete curing temperature profile as a function of time during at least a portion of the concrete curing process.

In another disclosed embodiment, the present invention comprises an apparatus. The apparatus comprises an insulated container sized and shaped for containing a quantity of water and at least one concrete cylinder submerged in and surrounded by the quantity of water, a heating element in communication with the quantity of water and a temperature sensory in thermal communication with the quantity of water so that the temperature sensor detects the temperature of the quantity of water. The apparatus also comprises a computing device controlling the heating element so that heat is selectively added to the quantity of water and the computing device is programmed so that it controls the heating element such that the temperature of the quantity of water follows a predetermined concrete curing temperature profile as a function of time.

In another disclosed embodiment, the present invention comprises a method. The method comprises selectively adding heat to water in a container in which a curing concrete cylinder is submerged in and surrounded by the water such that the temperature of the curing concrete follows a predetermined temperature profile as a function of time during at least a portion of the concrete curing process.

In another embodiment, the present invention comprises a method. The method comprises placing plastic concrete in a thermally insulated container and detecting the temperature of the concrete. The method also comprises selectively adding heat to the concrete in response to the detected temperature of the concrete so as to control the temperature of the curing concrete according to a predetermined temperature profile as a function of time.

In another embodiment, the present invention comprises a method. The method comprises detecting the temperature of a quantity of curing concrete in a thermally insulated container and selectively adding heat to the curing concrete in response to the detected temperature thereof so that the temperature of the curing concrete follows a predetermined temperature profile as a function of time.

In another embodiment, the present invention comprises an apparatus. The apparatus comprises a temperature sensor for detecting the temperature of concrete within a container and an electric heating element for providing heat to concrete within container. The apparatus also comprises a controller connected to the electric heating element for adjusting the amount of heat produced by the heating element and a computing device connected to the temperature sensor so that the computing device can detect the temperature of the concrete within the container, the computing device being connected to the controller and programmed to control the amount of heat provided by the electric heating element so that the temperature of concrete in the container is controlled to follow a predetermined temperature profile as a function of time.

In another embodiment, the present invention comprises a method. The method comprises selectively adding heat to curing concrete in an insulated container such that the temperature of the curing concrete follows a predetermined temperature profile as a function of time during at least a portion of the concrete curing process.

In another embodiment, the present invention comprises a method. The method comprises selectively adding heat to and selectively removing heat from curing concrete such that the temperature of the curing concrete follows a predetermined temperature profile as a function of time during at least a portion of the concrete curing process.

Accordingly, it is an object of the present invention to provide an improved concrete curing system.

Another object of the present invention is to provide an improved method for curing concrete.

A further object of the present invention is to provide a system for curing concrete that controls the temperature of the concrete during the curing process according to a predetermined concrete curing temperature profile as a function of time.

Another object of the present invention is to provide a method for accelerating the maturity or equivalent age of concrete to achieve improved concrete strength.

Another object of the present invention is to provide a system for curing concrete such that the concrete develops its maximum strength as early as possible.

Yet another object of the present invention is to provide a system for curing concrete such that the concrete develops its maximum durability.

Another object of the present invention is to provide a system for curing concrete more quickly.

A further object of the present invention is to provide a system for curing concrete that controls the temperature of the concrete in a thermally insulated container according to a predetermined temperature profile as a function of time.

Another object of the present invention is to provide a system for curing concrete in an insulated container that lowers the maximum concrete temperature gradually over time at a predetermined rate to a predetermined temperature, thereby reducing or eliminating temperature shrinkage and/or cracking.

Another object of the present invention is to provide an improved standard for curing concrete.

A further object of the present invention is to provide a concrete curing container that can be selectively heated in a controlled manner to follow a predetermined concrete curing temperature profile as a function of time.

Another object of the present invention is to provide an electrically heated concrete curing container that can be selectively cooled in a controlled manner to follow a predetermined concrete curing temperature profile as a function of time.

These and other objects, features and advantages of the present invention will become apparent after a review of the following detailed description of the disclosed embodiments and the appended drawing and claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is the perspective view of a disclosed embodiment of an insulated concrete container and a schematic diagram of a disclosed embodiment of a predetermined temperature control system in accordance with the present invention.

FIG. 2 is the top plan view of a disclosed embodiment of the insulated concrete container shown in FIG. 1 and a schematic diagram of a disclosed embodiment of a temperature control system in accordance with the present invention.

FIG. 3 is cross-sectional view taken along the line 3-3 of the insulted container shown in FIG. 2.

FIG. 4 is a graph of concrete temperature versus elapsed concrete curing time of a disclosed embodiment of a predetermined temperature profile as a function of time for curing concrete in accordance with the present invention. An example of ambient temperature is also shown on the graph.

FIG. 5 is a flow diagram for controlling the insulated concrete container shown in FIGS. 1 and 2 for following a predetermined temperature profile for curing concrete.

FIG. 6 is a graph of concrete temperature versus elapsed concrete curing time of another disclosed embodiment of predetermined temperature profiles as a function of time for curing concrete in accordance with the present invention.

FIG. 7 is a graph of concrete temperature versus elapsed concrete curing time of another disclosed embodiment of predetermined temperature profiles as a function of time for curing concrete in accordance with the present invention.

DETAILED DESCRIPTION OF THE DISCLOSED EMBODIMENTS

The disclosures of U.S. Pat. Nos. 8,532,815; 8,636,941 and 8,545,749 are all incorporated herein by reference in their entirety.

Referring now to the drawing in which like numbers indicate like elements throughout the several views, there is shown in FIG. 1 a disclosed embodiment of an insulated container 10 in accordance with the present invention. The insulated container 10 is preferably an ice chest, such as the Yeti Tundra® cooler available from Yeti Coolers, Austin, Tex. An example of a Yeti cooler is also disclosed in U.S. Patent Application Publication No. 2012/0132657 (the disclosure of which is incorporated herein by reference in its entirety). The insulated container 10 has four sides 12, 14, 16, 18, a bottom 20 and a hinged top 22 that opens and closes. The construction of such coolers is well known in the art and the particular design of the insulated container 10 is not a critical feature of the present invention.

The insulated container 10 is provided with a water heating system. Disposed in the bottom of the insulated container 10 is an electric resistance heating element 24. The electric resistance heating element 24 produces heat when an electric current is passed there through. The electric resistance heating element 24 is formed in the shape of a loop within the insulated container 10.

Disposed above and covering the electric resistance heating element 24 is a foraminous plate 26. The foraminous plate 26 provides support for concrete cylinders, such as the concrete cylinders 28, 30, placed in the insulated container 10. The insulated container 10 contains a sufficient amount of water 32 so that the concrete cylinders 28, 30 are completely submerged in and surrounded by the water when the concrete cylinders are placed on the foraminous plate 26. The electric resistance heating element 24 is also submerged in the water 32 whereby the electric resistance heating element is in thermal communication with the water so that when an electric current is passed through the electric resistance heating element it heats the electric resistance heating element which in turn heats the water. By heating the water 32 in which the concrete cylinders 28, 30 are submerged and surrounded, the concrete cylinders can be heated, also; i.e., the concrete cylinders will assume the same temperature as the water in which they are immersed.

The insulated container 10 is optionally provided with a water cooling system 33. Optionally, disposed in the bottom of the insulated container 10 below the foraminous plate 26 is a cooling coil 34. The cooling coil 34 is connected at one end to a radiator coil 36, which is then connected to a compressor 38, which in turn is connected to the other end of the cooling coil. The cooling coil 34, radiator coil 36 and compressor 38 form a closed system, which is partially filled with a refrigerant fluid; i.e., a low boiling fluid, such as R-22, R-401A or R-401C. The compressor 38 compresses the refrigerant gas and changes it to a fluid. The hot refrigerant fluid flows from the compressor 38 to the radiator coil 36 where heat from the hot refrigerant fluid is radiated to the surroundings. The refrigerant fluid flows from the radiator coil 36 to an expansion valve (not shown) in the cooling coil 34. At the expansion valve, the refrigerant changes from a fluid to a gas. The refrigerant gas flows through the cooling coil 34. The cold refrigerant gas in the cooling coil 34 absorbs heat from the water 32 surrounding it. The refrigerant gas flow from the cooling coil 34 to the compressor 38, where the process is repeated. By operating the compressor 38, heat can be removed from the water 32 in the insulated container 10. By removing heat from the water 32 in which the concrete cylinders 28, 30 are submerged and surrounded, heat can be removed from the concrete cylinders, also. Thus, the water 32 in which the concrete cylinders 28, 30 are submerged and surrounded can be selectively heated or cooled by either passing an electric current through the electric resistance heating element 34 or by operating the compressor 38.

A temperature sensor 40 is disposed in the insulated container 10 and in thermal communication with the water 32 in the insulated container; i.e., the temperature sensor is submerged in the water. The temperature sensor 40 is connected to a computing device 42 by an electric circuit, such as by the wires 44. The computing device 42 is preferably a computer, a microprocessor or central processing unit (CPU) with EERAM function to store parameters or a specially programmed digital controller. The temperature sensor 40 measures the temperature of the water 32 in the insulated container 10.

The computing device 42 is connected to the temperature sensor 40 so that it can continuously, or periodically, read and store the temperature measured by the temperature sensors. The computing device 42 is connected to an electric resistance heating element controller 44 by an electric circuit, such as the wires 46. The electric resistance heating element controller 44 is connected to a source of electricity, such as 24, 60, 120 or 220 volts AC or 12 or 24 volts DC electric current, by wires (not shown). The lower voltages are preferred as they reduce or eliminate the chances of electrocution by a worker. The electric resistance heating element controller 44 is connected to the electric resistance heating element 24 by an electric circuit, such as by the wires 48, 50. The computing device 42 and the electric resistance heating element controller 44 are configured and programmed such that the computing device controls the amount of heat produced by the electric resistance heating element. Thus, the computing device 42 controls the amount of heat that is provided to the water 32 within the insulated container 10.

The computing device 42 is optionally connected to a compressor controller 52 by an electric circuit, such as the wires 54. The compressor controller 52 is connected to a source of electricity, such as 120 or 220 volts AC or 12 or 24 volts DC electric current, by wires (not shown). The lower voltages are preferred as they reduce or eliminate the chances of electrocution by a worker. The compressor controller 52 is connected to the compressor 38 by an electric circuit, such as by the wires 56. The computing device 42 and the compressor controller 52 are configured and programmed such that the computing device controls the amount of heat removed by the cooling coil 34. Thus, the computing device 42 controls the amount of heat that is removed from the water 32 within the insulated container 10.

Since the computing device 42 continuously or periodically measures the temperature of the water 32, and since the computing device controls the amount of heat added to the water 32 by the electric resistance heating element 24 and the amount of heat removed from the water by the cooling coil 34, the computing device can control the temperature of the water. Since the concrete cylinders 28, 30 are submerged in and surrounded by the water 32 in the insulated container 10, the computing device 42 therefore controls the temperature of the concrete cylinders. The foregoing is commercially available as the IntelliCure Match concrete curing box from Engius, Inc., Sill water, OK 74074 USA. It is also disclosed in U.S. Patent Application Publication No. 2013/0343734 (the disclosure of which is incorporated herein by reference in its entirety). Similar computer temperature controlled concrete curing boxes are available from other manufacturers.

An input device 58 is connected to the computing device 42 by an electric circuit, such as by the wires 59. The input device 58 allows a user to provide input to the computing device 42, such as programming, operating parameters and/or data input. In a disclosed embodiment of the present invention, the computing device is pre-programmed so as to control the temperature of the water 32, and therefore the temperature of the concrete cylinders 28, 30, according to a predetermined concrete curing temperature profile. In a disclosed embodiment of the present invention, the input device 58 can be a keyboard, a keypad, a touch screen, a hard disk drive, a flash drive, a memory stick, a disk drive, a compact disk, a DVD or a combination thereof.

FIGS. 4-6 shows graphs of various disclosed embodiments of concrete curing temperature profiles as a function of time. In these graphs, the temperature of the concrete is shown on the vertical axis and elapsed concrete curing time is shown on the horizontal axis. FIG. 4 shows a predetermined temperature profile as a function of time. FIG. 4 also shows ambient temperature as a function of time. Both of these graphs are examples of predetermined temperature profiles as a function of time that can be used with the present invention.

FIG. 6 shows a concrete curing temperature profile as a function of time for concrete cured in an insulated concrete form (Panel 3 Greencraft) and a concrete curing temperature profile as a function of time for concrete cured in a conventional concrete form. Both of these graphs are examples of predetermined temperature profiles as a function of time that can be used with the present invention.

FIG. 7 shows a concrete curing temperature profile as a function of time for concrete cured in an insulated concrete form (Greencraft form) and a concrete curing temperature profile as a function of time for concrete cured in a conventional concrete form. FIG. 7 also shows ambient temperature as a function of time. All three of these graphs are examples of predetermined temperature profiles as a function of time that can be used with the present invention.

As used herein the term “temperature profile” includes increasing the concrete temperature above ambient temperature over a period of time preferably in a non-linear manner followed by decreasing the concrete temperature over a period of time. The term “temperature profile” also includes increasing the temperature and decreasing the temperature of the concrete at least twice or multiple times, such as shown for the ambient temperature shown in FIG. 4 and the temperatures shown in FIGS. 6 and 7. The term “temperature profile” also includes increasing the temperature and decreasing the temperature at predetermined rates. The term “temperature profile” specifically does not include adding a constant amount of heat to the concrete followed by stopping adding heat to the concrete, such as would be involved when turning an electrically heated blanket, steam or heated concrete form on and then turning the heated blanket, steam or heated concrete form off. The term “temperature profile” specifically does not include heating the concrete to a desired temperature and then turning off the heat. The term “temperature profile” specifically does not include maintaining a constant preset temperature.

FIG. 5 shows a flow diagram for a disclosed embodiment of a process for controlling the heat provided to curing concrete cylinders so that the temperature of the concrete can be controlled to match a desired temperature profile, such as that shown in FIGS. 4-6. The computing device 42 is programmed so that it will perform the process shown by this flow diagram.

The process starts at the block 100 and proceeds to the block 102 where a clock is initialized to time equal to zero and the clock is started. The clock measures the elapsed time from when the plastic concrete cylinder is placed into a concrete curing container, such as the insulated container 10 shown in FIGS. 1-3. This elapsed time therefore is a measure of the elapsed time for the curing of the concrete.

The process proceeds from the block 102 to the block 104 where the clock is read. The time that is read from the clock is then stored in a memory location, such as in the RAM memory of the computing device 42. The process proceeds from the block 104 to the decision block 106. A desired end time for terminating the process, such as 1 to 28 days, is preprogrammed into a memory location in the computing device 42. At the block 106, the clock time stored in the memory location is compared to the end time stored in the memory location of the computing device 42. If the clock time is less than the end time, the process proceeds to the block 108. If the clock time is greater than or equal to the end time, the process proceeds to the block 110 where the process is terminated.

At the block 108, the temperature from the water temperature sensor 40 is read and stored in a memory location, such as in the RAM memory of the computing device 42. The process then proceeds from the block 108 to the block 112.

At the block 112 the temperature value for the clock time stored in the memory location is determined from the predetermined temperature profile. This can be done from the temperature profile curve, such as the curve shown in FIGS. 4, 6 and 7. The clock time is found on the horizontal axis and the temperature is determined by finding the vertical axis component of the curve for the time corresponding to the clock time. When this temperature is determined, it is stored in a memory location, such as in the RAM memory of the computing device 42. In an alternate disclosed embodiment, instead of using a graph, such as shown in FIGS. 4-6, the temperature profile can be in the form of a lookup table. The lookup table lists a range of times and a profile temperature corresponding to each of the ranges of time. For example, for the time 20 hours to 21 hours, the corresponding profile temperature from the lookup table might be 45° C.; for the time 21 hours to 22 hours, the corresponding profile temperature from the lookup table might be 46° C. Of course, the time intervals for the lookup table can be longer or shorter than one hour and any useful or desirable time interval can be used for the lookup table, such as every minute, every 5 minutes or every fifteen minutes. Examples of lookup tables useful in the present invention are shown in Tables I to VI below. Tables I-III are examples of predetermined temperature profiles that includes a single peak temperature followed by a gradual cooling. Tables IV-VI are examples of predetermined temperature profiles that includes multiple heating and cooling cycles.

TABLE I Time Temp. (hrs) (° C.) 0 26 1 26 2 26 3 27 4 28 5 29 6 31 7 31 8 31 9 31 10 30 11 30 12 29 13 29 14 28 15 28 16 28 17 27 18 27 19 27 20 26 21 26 22 26 23 30 24 34 25 38 26 42 27 44 28 44 29 41 30 39 31 38 32 36 33 35 34 34 35 33 36 32 37 31 38 30 39 29 40 29 41 28 42 28 43 27 44 26 45 26 46 26

TABLE II Time Temp. (hrs) (° C.) 0 25 1 27 2 27 3 28 4 29 5 31 6 33 7 36 8 38 9 39 10 40 11 41 12 42 13 42 14 43 15 44 16 44 17 45 18 45 19 45 20 45 21 46 22 46 23 46 24 46 25 46 26 46 27 46 28 46 29 46 30 46 31 46 32 46 33 46 34 46 35 46 36 46 37 46 38 46 39 46 40 46 41 46 42 45 43 45 44 45 45 45 46 45 47 45 48 44 49 43 50 42 51 43 52 43 53 43 54 42 55 42 56 42 57 42 58 42 59 42 60 41 61 41 62 41 63 41 64 41 65 41 66 40 67 40 68 40 69 40 70 40 71 40 72 40 73 40 74 40 75 40 76 40 77 40 78 40 79 40 80 40 81 39 82 39 83 39 84 39 85 39 86 39 87 38 88 38 89 38 90 38 91 38 92 38 93 37 94 37 95 37 96 37 97 37 98 37 99 37 100 37 101 37 102 37 103 37 104 37 105 37 106 36 107 36 108 36 109 36 110 36 111 36 112 36 113 36 114 36 115 35 116 35 117 35 118 35 119 35 120 35 121 35 122 35 123 35 124 35 125 35 126 35 127 34 128 34 129 34 130 34 131 34 132 34 133 34 134 34 135 33 136 33 137 33 138 33 139 33 140 33 141 32 142 32 143 32 144 32 145 32 146 32 147 32 148 32 149 33 150 32 151 32 152 32 153 32 154 32 155 32 156 32 157 32 158 32 159 32 160 32 161 32 162 32 163 32 164 32 165 31 166 31 167 31 168 31 169 31 170 31 171 31 172 31 173 31 174 31 175 31 176 31 177 31 178 31 179 31 180 31 181 31 182 31 183 31 184 31 185 31 186 30 187 30 188 30 189 30 190 30 191 30 192 30 193 30 194 30 195 30 196 30 197 30 198 30 199 30 200 30 201 30 202 30 203 30 204 30 205 30 206 30 207 30 208 30 209 30 210 30 211 30 212 30 213 29 214 29 215 29 216 29 217 29 218 30 219 30 220 30 221 30 222 30 223 30 224 30 225 30 226 30 227 30 228 30 229 30 230 30 231 29 232 29 233 29 234 29 235 29 236 29 237 29 238 29 239 29 240 29 241 29 242 29 243 29 244 29

TABLE III Time Temp. (hrs) (° C.) 0 22 1 23 2 25 3 26 4 29 5 33 6 37 7 42 8 45 9 46 10 48 11 49 12 51 13 52 14 53 15 54 16 54 17 54 18 55 19 55 20 55 21 56 22 56 23 56 24 56 25 56 26 56 27 56 28 57 29 57 30 57 31 57 32 57 33 57 34 57 35 56 36 56 37 56 38 56 39 56 40 56 41 56 42 56 43 55 44 55 45 55 46 55 47 55 48 54 49 54 50 54 51 54 52 54 53 54 54 54 55 53 56 53 57 53 58 53 59 52 60 52 61 51 62 51 63 51 64 51 65 50 66 50 67 50 68 49 69 49 70 49 71 49 72 48 73 48 74 48 75 48 76 48 77 48 78 47 79 47 80 47 81 47 82 47 83 46 84 46 85 46 86 46 87 46 88 46 89 45 90 45 91 45 92 45 93 44 94 44 95 44 96 44 97 44 98 44 99 43 100 43 101 43 102 43 103 43 104 43 105 42 106 42 107 42 108 42 109 42 110 41 111 41 112 41 113 41 114 41 115 40 116 40 117 40 118 40 119 40 120 40 121 40 122 40 123 40 124 40 125 40 126 40 127 40 128 39 129 39 130 39 131 39 132 39 133 39 134 38 135 38 136 38 137 38 138 38 139 38 140 37 141 37 142 37 143 37 144 37 145 37 146 37 147 37 148 37 149 37 150 37 151 37 152 36 153 36 154 36 155 36 156 36 157 36 158 36 159 36 160 36 161 36 162 36 163 35 164 35 165 35 166 35 167 35 168 35 169 35 170 35 171 35 172 35 173 35 174 35 175 34 176 34 177 34 178 34 179 34 180 34 181 34 182 34 183 34 184 33 185 33 186 33 187 33 188 33 189 33 190 32 191 32 192 32 193 32 194 32 195 32 196 32 197 32 198 32 199 32 200 32 201 31 202 31 203 31 204 31 205 31 206 31 207 30 208 30 209 30 210 30 211 30 212 30 213 29 214 29 215 29 216 29 217 29 218 29 219 29 220 29 221 29 222 29 223 29 224 29 225 29 226 29 227 29 228 28 229 28 230 28 231 28 232 28 233 28 234 27 235 27 236 27 237 27 238 27 239 27 240 27 241 27 242 27 243 27 244 27 245 27 246 27 247 27 248 26 249 26 250 26 251 26 252 26 253 26 254 26 255 26 256 26 257 26 258 26 259 26 260 26 261 26 262 26 263 25 264 25 265 25 266 25 267 25 268 25 269 25 270 25 271 25 272 25 273 25 274 25 275 25 276 25 277 25 278 25 279 25 280 25 281 24 282 24 283 24 284 24 285 24 286 24 287 24 288 24 289 24 290 24 291 24 292 24 293 24 294 24 295 24 296 23 297 23 298 23 299 23 300 23 301 23 302 23 303 23 304 23 305 23 306 23 307 23 308 23 309 22 310 22 311 22 312 22 313 22 314 22 315 22 316 22 317 22 318 22 319 22 320 22 321 22 322 22 323 22 324 22 325 22 326 22 327 22 328 22 329 22 330 21 331 21 332 21 333 21 334 21 335 21 336 21

TABLE IV Time Temp. (hrs) (° C.) 0 26 1 26 2 26 3 27 4 28 5 29 6 31 7 31 8 31 9 31 10 30 11 30 12 29 13 29 14 28 15 28 16 28 17 27 18 27 19 27 20 26 21 26 22 26 23 30 24 34 25 38 26 42 27 44 28 44 29 41 30 39 31 38 32 36 33 35 34 34 35 33 36 32 37 31 38 30 39 29 40 29 41 28 42 28 43 27 44 26 45 26 46 26 47 29 48 31 49 31 50 34 51 38 52 37 53 36 54 35 55 34 56 34 57 33 58 31 59 30 60 29 61 29 62 28 63 28 64 27 65 27 66 26 67 26 68 26 69 26 70 27 71 29 72 31 73 32 74 33 75 36 76 38 77 37 78 36 79 35 80 33 81 32 82 32 83 31 84 30 85 29 86 29 87 29 88 28 89 28 90 27 91 27 92 27 93 27 94 27 95 29 96 31 97 34 98 36 99 38 100 39 101 37 102 36 103 35 104 34 105 33 106 32 107 31 108 30 109 29 110 29 111 28 112 27 113 27 114 26 115 26 116 26 117 26 118 26 119 29 120 32 121 34 122 35 123 36 124 36 125 36 126 35 127 33 128 32 129 32 130 31 131 30 132 29 133 28 134 28 135 27 136 26 137 26 138 26 139 25 140 25 141 25 142 25 143 29 144 32 145 36 146 39 147 41 148 42 149 40 150 38 151 37 152 36 153 34 154 33 155 32 156 31 157 30 158 29 159 29 160 28 161 28 162 27 163 26 164 26 165 26 166 27 167 29 168 32 169 33 170 33 171 35 172 36 173 34 174 33 175 33 176 32 177 31 178 30 179 29 180 29 181 28 182 28 183 27 184 27 185 26 186 26 187 26 188 26 189 26 190 26 191 29 192 32 193 35 194 37 195 39 196 40 197 39 198 37 199 36 200 35 201 34 202 32 203 32 204 31 205 30 206 29 207 29 208 28 209 28 210 27 211 27 212 27 213 27 214 27 215 29 216 32 217 35 218 37 219 39 220 39 221 38 222 37 223 36 224 35 225 33 226 32 227 32 228 31 229 30 230 29 231 29 232 29 233 28 234 28 235 27 236 27 237 27 238 27 239 29 240 32 241 35 242 37 243 39 244 40 245 39 246 38 247 37 248 36 249 35 250 33 251 32 252 32 253 31 254 30 255 30 256 29 257 29 258 28 259 28 260 28 261 28 262 28 263 30 264 34 265 36 266 38 267 39 268 39 269 38 270 37 271 37 272 33 273 32 274 31 275 30 276 29 277 29 278 29 279 29 280 28 281 28 282 27 283 27 284 27 285 27 286 27 287 29 288 33 289 37 290 40 291 42 292 43 293 41 294 40 295 38 296 37 297 36 298 35 299 33 300 33 301 32 302 32 303 31 304 31 305 30 306 29 307 29 308 29 309 29 310 30 311 32 312 35 313 38 314 40 315 41 316 40 317 40 318 39 319 38 320 36 321 36 322 34 323 33 324 33 325 32 326 32 327 31 328 30 329 30 330 29 331 29 332 29 333 29 334 29 335 31 336 34

TABLE V Time Temp. (hrs) (° C.) 0 21 1 21 2 22 3 23 4 22 5 23 6 24 7 24 8 25 9 24 10 23 11 23 12 23 13 23 14 23 15 22 16 22 17 22 18 22 19 22 20 22 21 21 22 22 23 22 24 23 25 25 26 26 27 30 28 31 29 30 30 29 31 29 32 29 33 29 34 28 35 26 36 25 37 24 38 23 39 23 40 22 41 21 42 21 43 20 44 20 45 20 46 20 47 23 48 25 49 28 50 29 51 31 52 32 53 33 54 31 55 31 56 29 57 29 58 28 59 26 60 23 61 22 62 22 63 21 64 22 65 22 66 22 67 21 68 21 69 21 70 22 71 23 72 24 73 25 74 26 75 26 76 25 77 28 78 29 79 29 80 29 81 27 82 26 83 26 84 25 85 24 86 23 87 23 88 23 89 22 90 21 91 21 92 21 93 21 94 21 95 23 96 24 97 26 98 26 99 29 100 29 101 29 102 29 103 28 104 28 105 27 106 26 107 25 108 24 109 23 110 22 111 21 112 20 113 20 114 20 115 19 116 18 117 18 118 19 119 21 120 24 121 26 122 26 123 28 124 27 125 28 126 28 127 28 128 27 129 26 130 26 131 25 132 23 133 22 134 20 135 20 136 19 137 18 138 17 139 17 140 17 141 16 142 18 143 21 144 24 145 26 146 28 147 32 148 32 149 32 150 31 151 29 152 29 153 27 154 26 155 24 156 23 157 22 158 21 159 21 160 20 161 19 162 19 163 18 164 18 165 18 166 19 167 21 168 24 169 26 170 29 171 31 172 31 173 31 174 31 175 30 176 28 177 28 178 26 179 25 180 24 181 23 182 22 183 21 184 21 185 20 186 20 187 20 188 19 189 19 190 20 191 22 192 25 193 27 194 29 195 32 196 32 197 32 198 32 199 31 200 30 201 30 202 28 203 26 204 25 205 23 206 23 207 22 208 21 209 20 210 20 211 20 212 20 213 20 214 20 215 23 216 26 217 28 218 29 219 32 220 32 221 33 222 32 223 31 224 30 225 29 226 28 227 26 228 25 229 24 230 23 231 23 232 22 233 21 234 21 235 21 236 20 237 20 238 21 239 23 240 26 241 28 242 30 243 32 244 33 245 34 246 33 247 31 248 31 249 30 250 29 251 28 252 26 253 25 254 24 255 23 256 23 257 23 258 22 259 21 260 21 261 21 262 22 263 24 264 27 265 29 266 32 267 34 268 34 269 34 270 34 271 33 272 32 273 32 274 23 275 22 276 22 277 23 278 23 279 23 280 23 281 23 282 22 283 22 284 22 285 21 286 22 287 23 288 26 289 28 290 29 291 33 292 34 293 34 294 33 295 32 296 32 297 29 298 29 299 29 300 27 301 26 302 26 303 26 304 25 305 25 306 24 307 24 308 24 309 23 310 24 311 24 312 27 313 29 314 31 315 34 316 35 317 34 318 33 319 34 320 32 321 30 322 29 323 28 324 27 325 26 326 26 327 25 328 24 329 24 330 23 331 23 332 23 333 23 334 23 335 23 336 26

TABLE VI Time Temp. (hrs) (° C.) 0.00 20 0.25 18 0.50 17 0.75 17 1.00 20 1.25 22 1.50 21 1.75 21 2.00 20 2.25 20 2.50 20 2.75 20 3.00 20 3.25 20 3.50 19 3.75 19 4.00 19 4.25 19 4.50 19 4.75 19 5.00 19 5.25 19 5.50 19 5.75 20 6.00 20 6.25 20 6.50 20 6.75 20 7.00 20 7.25 20 7.50 20 7.75 20 8.00 20 8.25 20 8.50 20 8.75 20 9.00 20 9.25 20 9.50 20 9.75 20 10.00 20 10.25 20 10.50 20 10.75 20 11.00 20 11.25 20 11.50 20 11.75 20 12.00 20 12.25 20 12.50 20 12.75 20 13.00 20 13.25 20 13.50 20 13.75 20 14.00 20 14.25 19 14.50 19 14.75 18 15.00 18 15.25 18 15.50 18 15.75 17 16.00 17 16.25 17 16.50 17 16.75 17 17.00 17 17.25 17 17.50 17 17.75 17 18.00 17 18.25 17 18.50 17 18.75 17 19.00 17 19.25 17 19.50 17 19.75 17 20.00 17 20.25 17 20.50 17 20.75 17 21.00 17 21.25 16 21.50 16 21.75 16 22.00 16 22.25 16 22.50 16 22.75 16 23.00 16 23.25 16 23.50 16 23.75 16 24.00 16 24.25 16 24.50 16 24.75 16 25.00 16 25.25 16 25.50 17 25.75 17 26.00 17 26.25 17 26.50 17 26.75 17 27.00 17 27.25 17 27.50 17 27.75 17 28.00 17 28.25 17 28.50 17 28.75 17 29.00 17 29.25 17 29.50 17 29.75 17 30.00 17 30.25 17 30.50 17 30.75 17 31.00 17 31.25 17 31.50 17 31.75 17 32.00 17 32.25 18 32.50 18 32.75 18 33.00 18 33.25 18 33.50 18 33.75 18 34.00 18 34.25 18 34.50 18 34.75 18 35.00 18 35.25 17 35.50 17 35.75 17 36.00 17 36.25 17 36.50 17 36.75 17 37.00 17 37.25 17 37.50 17 37.75 17 38.00 17 38.25 17 38.50 17 38.75 17 39.00 17 39.25 17 39.50 17 39.75 17 40.00 17 40.25 17 40.50 17 40.75 17 41.00 17 41.25 17 41.50 17 41.75 17 42.00 17 42.25 17 42.50 17 42.75 17 43.00 17 43.25 17 43.50 17 43.75 17 44.00 17 44.25 17 44.50 17 44.75 17 45.00 17 45.25 17 45.50 17 45.75 17 46.00 17 46.25 17 46.50 17 46.75 17 47.00 17 47.25 17 47.50 17 47.75 17 48.00 17 48.25 17 48.50 17 48.75 17 49.00 17 49.25 17 49.50 17 49.75 17 50.00 17 50.25 17 50.50 17 50.75 17 51.00 17 51.25 17 51.50 17 51.75 17 52.00 17 52.25 17 52.50 17 52.75 17 53.00 17 53.25 17 53.50 17 53.75 17 54.00 17 54.25 17 54.50 17 54.75 17 55.00 17 55.25 17 55.50 17 55.75 17 56.00 17 56.25 17 56.50 17 56.75 17 57.00 17 57.25 17 57.50 17 57.75 17 58.00 17 58.25 17 58.50 17 58.75 17 59.00 17 59.25 17 59.50 17 59.75 17 60.00 17 60.25 17 60.50 17 60.75 17 61.00 17 61.25 17 61.50 17 61.75 17 62.00 17 62.25 17 62.50 17 62.75 17 63.00 17 63.25 17 63.50 17 63.75 17 64.00 17 64.25 17 64.50 17 64.75 17 65.00 16 65.25 16 65.50 16 65.75 16 66.00 16 66.25 16 66.50 16 66.75 16 67.00 16 67.25 16 67.50 16 67.75 16 68.00 16 68.25 16 68.50 16 68.75 16 69.00 16 69.25 16 69.50 15 69.75 15 70.00 15 70.25 15 70.50 15 70.75 15 71.00 15 71.25 15 71.50 15 71.75 15 72.00 15 72.25 15 72.50 15 72.75 15 73.00 15 73.25 15 73.50 15 73.75 16 74.00 16 74.25 16 74.50 16 74.75 16 75.00 17 75.25 17 75.50 17 75.75 17 76.00 18 76.25 18 76.50 18 76.75 18 77.00 18 77.25 18 77.50 18 77.75 18 78.00 18 78.25 18 78.50 19 78.75 19 79.00 19 79.25 19 79.50 19 79.75 20 80.00 20 80.25 20 80.50 21 80.75 21 81.00 22 81.25 22 81.50 22 81.75 21 82.00 21 82.25 21 82.50 20 82.75 20 83.00 20 83.25 20 83.50 20 83.75 20 84.00 20 84.25 20 84.50 20 84.75 20 85.00 20 85.25 19

The predetermined temperature profiles, as shown in Tables I-VI above, may be useful for specific concrete mix designs. Other predetermined temperature profiles may be appropriate for other concrete mix designs. Of course, any desired temperature profile can be used as the predetermined temperature profile for use in the present invention. An advantage of the present invention is that it can be used to determine an optimal predetermined concrete curing temperature profile to produce concrete of a specific concrete mix design having desired improved physical properties, such as compressive strength, permeability, and the like. Once an optimal predetermined concrete curing temperature profile is determined, it can then be replicated at a construction site for that specific concrete mix design using a temperature controllable concrete form, such as the concrete forming systems disclosed in U.S. Pat. No. 8,532,815 and applicant's co-pending patent application Ser. No. 13/834,697 filed Mar. 15, 2013 and Ser. No. 14/275,833 filed May 12, 2014 (the disclosures of which are all incorporated herein by reference in their entirety). This allows the production of concrete cured under desired, reproducible conditions, which thereby assures the desired physical properties of the concrete.

The process then proceeds from the block 112 to the decision block 114. At the decision block 114 the temperature of the water is compared to the profile temperature corresponding to the stored clock time. If the water temperature is greater than the profile temperature, the process proceeds to the block 118. When this condition is encountered, the water temperature is greater than the profile temperature, so it is necessary to reduce the temperature of the water. At the block 118 the temperature of the water is reduced. This can be done in one of two ways. It can be done in an active manner where the water is actively cooled or it can be done in a somewhat passive manner where the amount of heat provided to the water by the electric resistance heating element 24 is reduced and the temperature of the water is allowed to reduce by heat leaking through the insulated walls of the concrete curing container 10. If the concrete curing container 10 is equipped with the optional water cooling system 32, for the actively cooled system, a signal is sent from the computing device 42 to the compressor controller 52 to turn on the compressor 38. Coolant is then circulated through the cooling coil 34 and heat is removed from the water 32. The other way of cooling the water 32 is for the computing device to send a signal to the electric resistance heating element controller 44 to reduce the amount of heat produced by the electric resistance heating element 24. This can be done by reducing the voltage of the electricity provided to the electric resistance heating coil or by reducing the time that the electric resistance heating element 24 is energized. The process then from the block 118 to the block 120. At the block 120, a predetermined wait time is executed before the process proceeds from the block 120 to the block 104 where a new clock time is read. The wait time can be any desired time that is suitable for the water temperature being measured, such as one second, ten seconds, 30 seconds, one minute, one hour and the like. If the water temperature of the concrete is less than or equal to the profile temperature, the process proceeds from the block 114 to the decision block 116.

At the decision block 116, the water temperature is compared to the profile temperature corresponding to the stored clock time. If the water temperature is equal to the profile temperature, the process proceeds from the block 116 to the block 120. If the water temperature is not equal to the profile temperature, the process proceeds to the decision block 122.

At the decision block 122, the water temperature is compared to the profile temperature. If the water temperature is greater than or equal to the profile temperature, the process proceeds to the block 120. If the water temperature is less than the profile temperature, the process proceeds to the block 124.

At the block 124, the temperature of the water is increased. This can be done by the computing device 42 sending a signal to the electric resistance heating coil controller 44 to increase the temperature of the electrically resistance heating coil. This can be done by increasing the voltage of the electricity provided to the electric resistance heating coil or by increasing the time that the electric resistance heating coil is energized. The process then proceeds from the block 124 to the block 126.

At the block 126, a predetermined wait time is executed before the process proceeds from the block 126 to the block 104. The wait time can be any desired time that is suitable for the water temperature being measured, such as one second, ten seconds, 30 seconds, one minute, one hour and the like. The process then proceeds from the block 126 to the block 104 where a new clock time is read.

The foregoing process regulates the heat added to the water by the electric resistance heating coil 24 or removed from the water by the cooling system 33 so that the temperature of the water is equal to the profile temperature at any given time. When the temperature of the water is less than the profile temperature at a given curing time, the electric resistance heating coil 24 provides heat to the water until the temperature of the water is equal to the profile temperature. When the temperature of the water 32 is greater than the profile temperature at a given curing time, no additional heat or a reduced amount of heat or heat is actively removed from the water. Thus, the temperature of the water 32 is continuously monitored and adjusted so that over time the water temperature will follow the predetermined temperature profile. Thus, over a predetermined time period the water temperature is maintained at predetermined levels that reduce to ambient temperature at a predetermined rate.

The present invention can be used with any concrete mix. Concrete comprises one or more cementitious materials, aggregate and water sufficient to hydrate the cementitious material. The particular concrete mix is not a critical feature of the present application. Traditional concrete uses portland cement as the only cementitious material in the concrete. However, any hydraulic cement or combination of hydraulic cements can be used as the cementitious material. Chemical admixtures and/or mineral admixtures can also be used.

It should be understood, of course, that the foregoing relates only to certain disclosed embodiments of the present invention and that numerous modifications or alterations may be made therein without departing from the spirit and scope of the invention as set forth in the appended claims. 

1-7. (canceled)
 8. A concrete curing device comprising: a thermally insulated container sized and shaped for containing a quantity of water and a quantity of concrete surrounded by the quantity of water; a heating element in thermal communication with the quantity of water and operative to add heat to the quantity of water; a cooling element in thermal communication with the quantity of water and operative to remove heat from the quantity of water; a temperature sensory in thermal communication with the quantity of water so that the temperature sensor detects the temperature of the quantity of water; a computing device controlling the heating element and cooling element so that heat is selectively added to and removed from the quantity of water; a memory device having a predetermined temperature profile stored therein, wherein the predetermined temperature profile varies temperature as a function of time and comprises a first period of temperature increase followed by a first period of temperature decrease followed by a second period of temperature increase followed by a second period of temperature decrease, wherein the predetermined temperature profile comprises a plurality of temperatures and each temperature's corresponding elapsed time from initiation of the predetermined temperature profile, and wherein the computing device is operatively associated with the temperature sensor for repeatedly comparing the detected temperature of the quantity of water to the temperature of the predetermined temperature profile corresponding to the time of the detected temperature.
 9. (canceled)
 10. The concrete curing device of claim 8, wherein the predetermined temperature profile covers a period of time from initiation to between 1 and 14 days. 